KR20160083917A - Electromagnetic flowmeter - Google Patents

Abstract

The electromagnetic flowmeter of the embodiment includes: a measurement tube through which an object to be measured flows; a first coil provided radially outward of the measurement tube to generate a magnetic field in the measurement tube; A second coil provided in the circumferential direction of the measuring tube and generating the magnetic field in the measuring tube; a core member inserted in the radial direction of the measuring tube, on the inner circumferential side of the first coil and the second coil, And an electrode portion for detecting an induced electromotive force generated when the measured object traverses the magnetic field, wherein an inner circumference of the first coil, an inner circumference of the second coil, Has a shape insertable into the inner periphery of the first coil and the inner periphery of the second coil.

Description

ELECTROMAGNETIC FLOWMETER

An embodiment of the present invention relates to an electronic flow meter.

The electromagnetic flowmeter is a flowmeter that utilizes the generation of an induced electromotive force according to a flow rate when a conductive fluid flows in a magnetic field. In order to generate this magnetic field, a permanent magnet or an excitation coil is used. In general, an excitation coil is provided so as to face the outside of a measuring tube (detector) including a nonmagnetic material, Quot; current ") to generate a magnetic field inside the measuring tube.

In the case of an electromagnetic flowmeter, it is necessary to prepare various kinds of coils because there are various measuring pipes of various diameters and it is necessary to change the size and shape of the coils for each aperture. Further, there is a problem that it is difficult to adjust the distribution of the magnetic field in the measuring tube in the large-sized coil for application to the large-diameter electromagnetic flowmeter.

Japanese Patent Laid-Open No. 2001-281028

SUMMARY OF THE INVENTION An object of the present invention is to provide an electromagnetic flowmeter in which a coil unit including a coil for generating a magnetic field, which is provided in a measuring tube for flowing an object to be measured, can be formed into a small number of kinds of parts.

In order to solve the above problems, an electromagnetic flowmeter according to an embodiment includes a measuring tube through which an object to be measured flows, a first coil provided outside the measuring tube in a radial direction thereof and generating a magnetic field in the measuring tube, A second coil provided in the circumferential direction of the measuring tube so as to form a pair with the first coil and the second coil and generating a magnetic field in the measuring tube; And an electrode portion provided in the measuring tube and detecting an induced electromotive force generated when the measured object flows into the measuring tube, wherein the inner portion of the first coil and the inner portion of the second coil And the outer diameter of the core member have a shape in which a plurality of the core members can be inserted into the inner periphery of the first coil and the inner periphery of the second coil.

1 is a perspective view of an electronic flowmeter according to a first embodiment of the present invention;
2 is a cross-sectional view of the electromagnetic flowmeter of FIG. 1 along the detector AA;
3 is a cross-sectional view of the electromagnetic flow meter of Fig. 2 along the detector BB; Fig.
Fig. 4 is a cross-sectional view of the coil unit of the electromagnetic flowmeter in Fig. 3 in CC. Fig.
5 is a sectional view of a detector of an electromagnetic flowmeter according to a second embodiment of the present invention.
6 is a cross-sectional view of the detector DD of the electromagnetic flowmeter in Fig. 5; Fig.
7 is a sectional view of a detector of an electromagnetic flowmeter according to a third embodiment of the present invention.
8 is a cross-sectional view of the detector EE of the electromagnetic flowmeter in Fig. 7; Fig.
9 is a sectional view of a detector of an electromagnetic flowmeter according to a fourth embodiment of the present invention.
Fig. 10 is a cross-sectional view of the detector FF of the electromagnetic flowmeter in Fig. 9; Fig.
11 is a sectional view of a detector of an electromagnetic flowmeter according to a fifth embodiment of the present invention.
Fig. 12 is a cross-sectional view of the detector GG of the electromagnetic flowmeter in Fig. 11; Fig.
13 is a sectional view of a detector of an electromagnetic flowmeter according to a sixth embodiment of the present invention.
14 is a view of a piping of an electromagnetic flowmeter as a seventh embodiment of the present invention.
15 is a view of an adjusting mechanism of an electromagnetic flowmeter as a seventh embodiment of the present invention.

Hereinafter, embodiments of the electromagnetic flowmeter will be described with reference to the drawings.

(First Embodiment)

1 is a perspective view of an electronic flowmeter according to a first embodiment of the present invention. The electromagnetic flowmeter 1 includes a detector 2 for detecting an induced electromotive force generated when a conductive object to be measured flows in the measuring tube and a converter 3 for converting the detected signal of the induced electromotive force into a flow rate value And a connection portion 13, as shown in Fig. The electromagnetic flowmeter 1 can be configured as an electromagnetic flowmeter of an always-excitation mode (alternating excitation mode), for example.

The detector 2 has a tube 7 in which a flow path 7a is provided and a detection part 14 that detects the flow rate of the fluid to be measured flowing in the flow path 7a. The tubular body 7 has a measuring tube 4, a flange 5, a lining 6, and a case 20.

The converter (3) has a housing (10) and a display device (12). The display screen 12a of the display device 12 is covered with the panel 11. [ The converter 3 converts the magnitude of the induced electromotive force detected by the detector 2 to the flow rate of the measured object flowing in the flow path 7a of the measuring tube 4. [ The value of the converted flow rate is displayed on the display device 12 of the converter 3.

The connection section 13 connects the detector 2 and the transducer 3. The inside of the connection portion 13 is provided with a wiring or the like for electrically connecting the detector 2 and the converter 3. The wiring or the like transmits the induced electromotive force detected by the detector 2 to the transducer 3. The wiring or the like transfers the excitation current flowing through the coil unit 8 to be described later disposed in the detector 2 from the outside of the electromagnetic flowmeter 1 to the detector 2 through the converter 3 .

The flange 5 is provided on the upstream and downstream ends of the measuring pipe 4. The flange 5 is a joining portion for joining the detector 2 with the piping (not shown) on the upstream side and the downstream side. The flange 5 has a bonding surface 5a on both the upstream side and the downstream side of the detector 2 and has a plurality of holes 5b on the surface of the bonding surface 5a. The flange 5 is joined to the joint surface 5a by overlapping the joint surfaces of the upstream and downstream pipes through which the measured object flows. At this time, the plurality of holes 5b are overlapped with the holes existing in the joining surfaces of the separate tubes, and are joined with bolts, nuts, or the like for connection.

The lining 6 is provided on the inner surface 4b of the measuring tube 4. [ The lining 6 is an insulator covering the inside of the measuring pipe 4. A lining 6 is provided inside the measuring tube 4 of the tubular body 7 to form a flow path 7a through which the object to be measured flows. The lining 6 promotes chemical resistance, heat resistance, and adhesion resistance of the measurement tube 4 to the object to be measured. The lining 6 also prevents leakage of the induced electromotive force generated by the magnetic field and the measured object to the measuring tube 4. [ The lining 6 may be constituted by, for example, a fluororesin or the like.

2 is a cross-sectional view of the electromagnetic flow meter detector 2 according to the first embodiment of Fig. 1 taken along line A-A. That is, Fig. 2 is a sectional view in a plane parallel to the direction in which the measured object flows. 2 shows a portion between the flanges 5 at both ends of the detector 2, and the flange 5 is not shown. 3 is a cross-sectional view of the electromagnetic flow meter detector 2 of Fig. 2 taken along the line B-B, and is a sectional view of the inside of the case 20 (not shown). That is, Fig. 3 is a cross-sectional view in a plane orthogonal to the direction in which the measured object flows.

The case 20 includes a peripheral wall portion 15 and a peripheral wall portion 16. The case 20 is connected to a converter 3, which will be described later, via a connecting portion 13. The case 20 is a peripheral wall portion covering the coil unit 8, which will be described later, disposed radially outward of the measuring tube 4, and is welded to the measuring tube 4.

The detecting portion 14 has a pair of coil units 8 and 8 and a pair of electrode portions 9 and 9 (only one is shown in Fig. 2) to be in contact with the measured object. The pair of coil units 8 and 8 generate a constant magnetic field in the inner flow path 7a of the measuring tube 4. [ The pair of electrode portions 9 and 9 detect an induced electromotive force generated when the object to be measured flowing through the flow path 7a passes through the magnetic field.

Axis Ax is the axis center of the measuring tube 4 of the detector 2. Further, the measured object flows in the same direction as the axial center Ax (x-axis direction = axial direction of the measuring tube 4) of the flow path 7a of the measuring tube 4. [ The measurement tube 4 has an outer surface 4a as a first surface and an inner surface 4b as a second surface. A base member 17 is provided on the outer surface 4a. The base member 17 is provided with a coil unit 8. An outer member 19 is provided on the side opposite to the base member 17 of the coil unit 8. The case 20 is provided on the outer surface 4a so as to cover the base member 17, the coil unit 8 and the outer member 19. [ The case 20 is fixed by welding or the like. The flange 5 is provided on the outer surface 4a of the measuring tube 4. The pair of electrode portions 9 and 9 and the lining 6 are provided on the inner surface 4b of the measuring pipe 4. [ The line connecting the pair of electrode portions 9 and 9 is substantially orthogonal to the axis Ax of the measuring tube 4. [

The lining 6 has a cylindrical portion 6a (see Fig. 2) and a flared portion 6b (see Fig. 1). The cylindrical portion 6a covers the inner surface 4b of the measuring tube 4 and protects the inner surface 4b from the measured object. The flare portion 6b has an end face 6c. And the end face 6c constitutes the outer surface of the tube body 7. [ The flare portion 6b is in contact with the end face 5a (see Fig. 1) of the flange 5 and protects the end face 5a from the measured object.

The base member 17 has a first base member 17A and a second base member 17B which are disposed opposite to each other with the measurement tube 4 interposed therebetween. That is, the first base member 17A and the second base member 17B are provided on both sides with the axis Ax of the measuring tube 4 therebetween. The base member 17 includes a magnetic material. The base member 17 is fixed to the outer surface 4a of the measuring tube 4 by welding or the like. Each of the first base member 17A and the second base member 17B has a core member 21. The core member 21 is fixed from the base member 17 toward the outer side in the radial direction of the measuring pipe 4. The core member 21 is fixed to the base member 17 by welding or the like. The core member 21 is a core member of the coil unit 8.

The coil unit 8 has, for example, a cylindrical coil 8a. The inner periphery of the coil 8a can accommodate two or more core members 21. The coil unit 8 is provided in the first base member 17A and the second base member 17B and can insert two or more of the core members 21 in the cylinder of the coil 8a.

The outer member 19 is formed in a flat plate shape. The outer member 19 is provided corresponding to the first base member 17A and the second base member 17B. The outer member 19 is located on the opposite side from the base member 17 of the coil unit 8 via the coil 8a. The outer member 19 can be fixed to the core member 21 by welding or the like. Whereby the coil unit 8 is positioned between the base member 17 and the outer member 19. The outer member 19 can prevent the coil unit 8 from escaping out of the measuring tube 4 in the radial direction. The coil unit 8 also has the function of a supporting member for supporting the outer member 19.

4 is a cross-sectional view at C-C of the coil unit 8 of Fig. 4 is an example of the number and arrangement of the core members 21 inserted into the coil 8a. By arranging the four core members 21 as shown in Fig. 4 (a), the core member 21 of the coil unit 8 in Figs. 2 and 3 is arranged. The number of the core members 21 of the coil unit 8 may be changed to three, two, or one as shown in (b), (c), and (d) By changing the fixing position at the inner periphery of the coil 8a, the magnetic field distribution in the measuring tube 4 fluctuates, and the detection accuracy of the induced electromotive force of the pair of electrode portions 9, 9 can be improved. The arrangement of the plurality of core members 21 is, for example, arranged in the circumferential direction of the same distance from the center of the inner periphery of the coil 8a. The number and arrangement of the core members 21 to be inserted into the coil 8a are not limited to those shown in Fig. 4, .

The magnetic flux generated inside the coil unit 8 spreads along the outer surface 4a of the measuring tube 4 by the base member 17 by applying the exciting current to the coil 8a. The spread magnetic flux flows from one of the first base members 17A toward the other of the second base members 17B so as to traverse the flow path 7a in the measuring tube 4. [ The distribution of the magnetic field generated in the flow path 7a in the measuring tube 4 changes by changing the number of the core members 21 inserted into the coil 8a and the fixing position of the core member 21. [ In addition, since the number of magnetic fluxes generated increases as the number of core members 21 inserted into the coils 8a increases, the density of the magnetic flux increases.

In the present embodiment, the base member 17 is provided with a plurality of coil units 8 spaced apart from each other in the axial direction (x direction) of the measuring tube 4. In this case, the density of the magnetic flux generated in the measuring tube 4 is increased through the base member 17. The coil 8a is the same component and the number of the core members 21 is the same as the number of the coil units 8 forming the pair by sandwiching the axis Ax of the measuring tube 4. [ It is necessary to adjust the magnetic field distribution in the measuring tube 4 in order to detect the induced electromotive force by the pair of electrode portions 9 and 9 of the detector 2 with high accuracy. The detection sensitivity of the induced electromotive force of the pair of electrode portions 9, 9 decreases as the distance from the pair of electrode portions 9, 9 in the axial direction of the measurement tube 4 decreases. Therefore, one core member 21 is inserted into the coil unit 8 close to the pair of electrode parts 9, 9, and the coil unit 8 located at a position apart from the pair of electrode parts 9, The strength of the generated magnetic field can be selected by inserting two core members 21 into the core 8.

In this embodiment, even if the diameter of the measuring tube 4 is different, the coil unit 8 is made common by using the same specification without changing the specifications of the coil 8a and the core member 21. [ That is, even if the diameter of the measuring tube 4 is different, specifications such as the winding number, diameter, shape, length, and size of the coil 8a and the length and thickness of the core member 21 can be the same , Sharing can be planned.

The strength of the magnetic field in the measuring tube 4 of another electromagnetic flowmeter having different diameters of the measuring tube 4 can be selected by changing the number of the core members 21 and changing the arrangement method thereof. When the diameter of the measuring tube 4 is increased, a strong magnetic field can be generated in the measuring tube 4 by increasing the number of the coil units 8. Thus, the labor required for manufacturing the electromagnetic flowmeter 1 can be reduced. In addition, it is possible to reduce the cost in that the coil unit 8 of a small number of kinds is changed from a production mode in which a small number of coil units 8 of various kinds are used to a production type in which a large number of coil units 8 are used.

2, between the outer member 19 and the peripheral wall portion 16 of the case 20, there is a gap (not shown) extending along the axial direction (x direction) of the measuring tube 4 A clearance 18 is provided. This makes it possible to absorb manufacturing variation (dimensional fluctuation) of the case 20, the base member 17, the outer member 19, and the like. It is also possible to easily and accurately carry out the work of mounting the case 20, the base member 17, the outer member 19, and the like on the measuring pipe 4 as compared with the case in which the gap 18 is not provided .

In the present embodiment, at least the peripheral wall portion 16 of the case 20 includes a magnetic material such as steel. The magnetic flux flowing from the first base member 17A through the measurement tube 4 to the second base member 17B flows along the circumferential direction in the peripheral wall portion 16, And returns to the first base member 17A through the gap 18. [ In other words, the peripheral wall portion 16 constitutes at least a part of the returning member.

It is possible to suppress the impact on the peripheral wall portion 16 from being transmitted to the coil unit 8 as compared with the conventional structure in which the return path is directly coupled to the core member 21 because the peripheral wall portion 16 is a return- So that the reliability of the electromagnetic flowmeter 1 can be enhanced. In addition, since the peripheral wall portion 16 constitutes a part of the return flow path, the electromagnetic flowmeter 1 can be made compact in comparison with the case where the return flow path and the peripheral wall portion 16 are formed of separate members .

Further, the present embodiment illustrates a contact-type electromagnetic flowmeter in which an object to be measured and an electrode section are in contact with each other. However, in the present invention, the present invention is not limited to this type of contact type electromagnetic flowmeter, and it may be a non-contact type electromagnetic flow meter in which other measurement type, for example, the object to be measured and the electrode part are not in contact with each other.

In the present embodiment, the coil unit 8 may be formed by hardening the coil 8a wound in a cylindrical shape by impregnation treatment. Alternatively, the coil 8a may be used, and the coil 8a may be wound in a cylindrical shape The coil unit 8 may be constituted.

According to the present embodiment, a constant magnetic field can be strongly generated in the measuring tube 4, and the detection accuracy of the induced electromotive force in the pair of electrode portions 9, 9 can be improved.

(Second Embodiment)

5 shows an example of the detector 2 of the electromagnetic flowmeter 1 according to the second embodiment and shows a portion between the flanges 5 at both ends of the detector 2. Fig. In the present embodiment, the pair of coil units 8 is increased in the axial direction (x-axis direction) as compared with the first embodiment. In the first embodiment, three pairs of coil units 8 are disposed in the present embodiment, compared to a case where two pairs of coil units 8 are arranged in the axial direction of the measuring tube 4 (see Fig. 2) (See FIG. 5). By increasing the number of the coil units 8, it is possible to strongly generate a magnetic field in the flow path 7a of the measuring pipe 4. [ Therefore, even when the diameter of the measuring tube 4 is larger than that of the first embodiment, the electrode portions 9, 9 can detect the induced electromotive force with high accuracy.

6 is a cross-sectional view of D-D of the electromagnetic flowmeter detector 2 of Fig. 5, and is a cross-sectional view of the inside of the case 20 (not shown). That is, Fig. 6 is a cross-sectional view in a plane perpendicular to the direction in which the measured object flows.

The coil units 8 are arranged in three pairs in the axial direction (x-axis direction) of the measuring tube 4. [ A plurality of pairs of coil units 8 includes a line connecting the pair of coil units 8 and 8 and a pair of electrode units 9 and 9 provided in the measuring tube 4 Are arranged so as to be orthogonal to each other (see Fig. 6). Here, the coil 8a constituting each coil unit 8 is the same as that of the first embodiment, and the core member 21 inserted into the coil unit 8 is also the same as that of the first embodiment .

Here, in order to detect the induced electromotive force by the pair of electrode portions 9, 9 of the detector 2 with high accuracy, it is necessary to adjust the magnetic field distribution in the measuring tube 4. The pair of coil units 8 at the left end and the right end of Fig. 5 are disposed at a greater distance from the pair of electrode units 9, 9 than the coil unit 8 at the center. The strength of the magnetic field generated from the pair of coil units 8 at the left end and the right end becomes weaker in the vicinity of the electrode portion 9 as compared with the magnetic field generated from the central coil unit 8, Lt; / RTI > As a result, the influence of the fluctuation due to the noise becomes strong. Thus, with respect to the coil unit 8 constituting a pair of both ends, the influence on the detection of the induced electromotive force of the pair of electrode portions 9, 9 is small. The pair of coil units 8 disposed at the center are arranged at a distance closer to one pair of electrode units 9 than the pair of coil units 8 constituting the pair of ends, 9, 9) on the detection of the induced electromotive force is increased. Therefore, the coil unit 8 constituting a pair at both ends can strongly generate a magnetic field generated in the measuring tube 4 by inserting a larger number of the core members 21 than the pair of coil units 8 at the center . For example, the number of the core members 21 inserted into the pair of coil units 8 at both ends may be two, and the number of the core members 21 inserted into the pair of coil units 8 at the center may be one . In addition, two or more core members 21 are inserted into a pair of coil units 8, and the coil unit 8 forming a pair at both ends is inserted more than the pair of coil units 8 at the center .

The arrangement of the core members 21 in the coil unit 8 can be changed in arrangement in each coil unit 8. [

In this embodiment, although three pairs of coil units 8 are shown in Fig. 5, the number of coil units 8 is not limited to that shown in Fig. In Fig. 6, the number of the core units 21 is four, but the number of the coil units 8 is not limited to Fig.

A uniform magnetic field can be strongly generated in the flow path 7a in the measuring tube 4 and the detection accuracy of the induced electromotive force in the pair of electrode portions 9 can be improved Loses.

(Third Embodiment)

7 shows an example of the detector 2 of the electromagnetic flowmeter 1 with respect to the third embodiment and shows a portion between the flanges 5 at both ends of the detector 2. Fig. 8 is a cross-sectional view of E-E of the electromagnetic flowmeter detector 2 of Fig. 7, and is a cross-sectional view of the inside of the case 20 (not shown). That is, Fig. 8 is a cross-sectional view in a plane perpendicular to the direction in which the measured object flows.

7, the coil unit 8 is arranged at a position passing through a pair of electrode portions 9, 9 (only one is shown in Fig. 7) of the measuring tube 4 in the axial direction One pair is arranged. 8, two pairs of coil units 8 (8A, 8B, 8C and 8D in Fig. 8) are arranged along the circumferential direction of the measuring tube 4, as shown in Fig. Here, the coils 8a constituting each coil unit 8 are the same parts as those of the first to second embodiments. The core member 21 inserted into the coil unit 8 is also the same as that of the first to second embodiments. The pair of coil units 8 are configured to sandwich the axis Ax. The pair of coil units 8 may be configured so as to oppose each other without interposing the axial center Ax. In Fig. 8, the constitution of pairing with the axial center Ax is a pair including a coil unit 8A and a coil unit 8B, and a pair including a coil unit 8C and a coil unit 8D. 8 is a configuration in which the coil unit 8A and the coil unit 8D are provided and the pair of coil units 8C and 8B It is a pair.

One of the two pairs of coil units 8 is connected to the measuring tube 4 by the first base member 17A and the other part of the two coil units 8 is connected to the second base member 17B . One of the two pairs of coil units 8 is connected by the outer member 19 and the other portion located on the opposite side is also connected by an outer member 19 different from that described above.

In the present embodiment, it is possible to increase or decrease the number of the core members 21 and to change the arrangement thereof with respect to each pair of coil units 8.

In the present embodiment, two pairs of coil units 8 are used in FIG. 8, but the number of pairs of coil units 8 may be three or more, and is not limited to the embodiment of FIG. At least one of the core members 21 inserted in the pair of coil units 8 is inserted into the pair of coil units 8 and inserted into the other coil units 8 The number of the core members 21 is not limited.

It is possible to strongly generate a constant magnetic field in the flow path 7a in the measuring tube 4 according to the present embodiment and to obtain an effect that the detection accuracy of the induced electromotive force in the pair of electrode portions 9, .

(Fourth Embodiment)

9 shows an example of the detector 2 of the electromagnetic flowmeter 1 with respect to the fourth embodiment in a portion between the flanges 5 at both ends of the detector 2. Fig. 10 is a cross-sectional view of F-F of the electromagnetic flowmeter detector 2 of Fig. 9, and is a sectional view of the inside of the case 20 (not shown). That is, Fig. 10 is a cross-sectional view in a plane perpendicular to the direction in which the measured object flows. In this embodiment, as compared with the first embodiment, the pair of coil units 8 is increased in the circumferential direction. In the first embodiment, a pair of coil units 8 are arranged on the outer peripheral portion of the measuring tube 4 with respect to the circumferential direction of the measuring tube 4 (see Fig. 3). In this embodiment, Three coil units 8 are arranged in the circumferential direction of the coil units 4 (see Fig. 10). A constant magnetic field can be strongly generated in the measuring tube 4 by increasing the number of the coil units 8 even when the diameter of the measuring tube 4 is larger than that of the first embodiment.

In this embodiment, as shown in Fig. 9, two pairs of coil units 8 are arranged along the axial direction (x-axis direction) of the measuring tube 4. [ 10, three pairs of coil units 8 (8A, 8B, 8C, 8D, 8E and 8F in Fig. 10) are arranged along the circumferential direction of the measuring tube 4 have. Here, the coils 8a constituting each coil unit 8 are the same parts as those of the first to third embodiments. The core member 21 to be inserted into the coil unit 8 is also the same as those of the first to third embodiments. In Fig. 10, the coil unit 8E and the coil unit 8F form a pair by sandwiching the axis Ax. And the remaining four coil units 8 are constituted by paired axes Ax. Further, the four coil units 8 may be configured so as to oppose each other without interposing the axial center Ax. In Fig. 10, the constitution of pairing with the axial center Ax is a pair including a coil unit 8A and a coil unit 8B, and a pair including a coil unit 8C and a coil unit 8D. 10 is a configuration in which the coil unit 8A and the coil unit 8D are included and the coil unit 8C and the coil unit 8B It is a pair.

One of the three pairs of coil units 8 is connected to the measuring tube 4 by the first base member 17A and the other of the three pairs of coil units 8 is located on the opposite side with the axis Ax of the measuring tube 4 therebetween Side portion is connected to the second base member 17B. One of the three pairs of coil units 8 is connected by the outer member 19 and the other part located on the opposite side with respect to the center axis Ax of the measuring tube 4, And is connected by a member 19.

In the present embodiment, it is possible to increase or decrease the number of the core members 21 and to change the arrangement thereof with respect to each pair of coil units 8.

In the present embodiment, three pairs of coil units 8 are used in Fig. 10, but the number of pairs of coil units 8 may be four pairs or more and is not limited to the embodiment of Fig. The core member 21 to be inserted into the pair of coil units 8 is inserted in the same number in at least one pair of coil units 8 and inserted into the other coil unit 8 The number of the core members 21 is not limited.

The electromagnetic flowmeter 1 of the present embodiment has a large diameter of the measuring tube 4 and is provided at a position spaced from a pair of electrode portions 9 and 9 (only one is shown in Fig. 9) A constant magnetic field can be strongly generated in the flow path 7a in the measurement tube 4 when the coil unit 8 is disposed and the detection accuracy of the induced electromotive force in the pair of electrode portions 9, Is improved.

(Fifth Embodiment)

11 shows an example of the detector 2 of the electromagnetic flowmeter 1 with respect to the fifth embodiment and shows a portion between the flanges 5 at both ends of the detector 2. Fig. 12 is a sectional view of the detector 2 of the electromagnetic flowmeter 1 of Fig. 11 taken along the line G-G and is a sectional view of the inside of the case 20 (not shown). That is, Fig. 12 is a cross-sectional view in a plane perpendicular to the direction in which the measured object flows. Compared with the first embodiment, this embodiment is assumed to be applied to an electromagnetic flowmeter having a diameter of the measuring tube 4 equal to that of the first embodiment.

The present embodiment has two pairs of coil units 8 and 8 arranged in the axial direction (x direction) of the measuring tube 4 and an annular member 30 (covering member) containing a magnetic material. The annular member 30 is formed by covering the pair of coil units 8 in the circumferential direction of the measuring tube 4. [ The annular member 30 is located on the side opposite to the base member 17 of the coil unit 8 and is welded to each of the core members 21 by welding or the like. Thus, the annular member 30 is a covering member of the coil unit 8. Further, the annular member 30 is an example of a return member. It is possible to strongly generate the magnetic field generated in the flow path 7a in the measuring tube 4 and to detect the induced electromotive force in the pair of electrode portions 9, 9 by providing the annular member 30 as a return- Precision can be improved.

Here, the coil unit 8 has, for example, a cylindrical coil 8a or the like. The inner periphery of the coil 8a can accommodate two or more core members 21. The effect of the present embodiment is that the magnetic field generated in the flow path 7a in the measuring tube 4 can be strengthened by changing the number of the core members 21 in the coil unit 8 .

(Sixth Embodiment)

13 is a sectional view of the detector 2 of the electromagnetic flowmeter 1 in a plane orthogonal to the direction in which the measured object flows, with respect to the sixth embodiment. The number of pairs of coil units 8 arranged in the circumferential direction of the measuring tube 4 is increased in the fifth embodiment. When the diameter of the measuring pipe 4 is larger, a magnetic field can be strongly generated in the flow path 7a of the measuring pipe 4 by increasing the pair of coil units 8 in the circumferential direction.

13, a coil unit 8 (8A, 8B, 8C, 8D, 8E, 8F in FIG. 13) is arranged in three pairs along the circumferential direction of the measuring tube 4. In Fig. 13, the coil unit 8E and the coil unit 8F form a pair by sandwiching the axis Ax. And the remaining four coil units 8 are constituted by paired axes Ax. Further, the four coil units 8 may be configured so as to oppose each other without interposing the axial center Ax. In Fig. 13, the constitution of pairing with the axial center Ax is a pair including a coil unit 8A and a coil unit 8B, and a pair including a coil unit 8C and a coil unit 8D. In Fig. 13, the configuration in which the coil units 8A and 8D are opposed to each other without interposing the axial center Ax means a pair including the coil unit 8A and the coil unit 8D and the pair including the coil unit 8C and the coil unit 8B It is a pair.

The plural pairs of coil units 8, 8 have, for example, a cylindrical coil 8a or the like. The inner periphery of the coil 8a can accommodate two or more core members 21. The present embodiment has an annular member 30, and the annular member 30 is an example of a return member. It is possible to strongly generate the magnetic field generated in the flow path 7a in the measuring tube 4 and to detect the induced electromotive force in the pair of electrode portions 9, 9 by providing the annular member 30 as a return- Precision can be improved.

The effect of the present embodiment is that the magnetic field generated in the flow path 7a in the measuring tube 4 can be strengthened by changing the number of the core members 21 in the coil unit 8 .

(Seventh Embodiment)

The electromagnetic flowmeter 1 in this embodiment has the same configuration as the electromagnetic flowmeter 1 in Fig. 14 is an example of piping of the electromagnetic flowmeter 1 of the present embodiment. On the left and right sides of the electromagnetic flow meter 1, there are other pipes and piping. The pipe on the left side is on the upstream side, and the measured object flows into the electromagnetic flowmeter 1 in the x-axis direction from the pipe on the left side.

The electromagnetic flowmeter 1 can be used with high accuracy by using the object to be measured while a certain amount of the object to be measured flows stably. Therefore, it is preferable that the electromagnetic flowmeter 1 is disposed between the straight pipe body on both the upstream side and the downstream side. When the diameter of the measuring tube of the electromagnetic flowmeter 1 is D, it is preferable that a tube having a length of 5D or more and a length of 5D or more of the diameter of the measuring tube is connected upstream and downstream from the detecting portion of the electromagnetic flowmeter.

However, depending on the piping of the tubular body, as shown in Fig. 14, a tubular body having a sufficiently long straight pipe length can not be taken, and the tubular body may be disposed adjacent to the 90-degree bending tube 31. [ The 90 degree bending pipe 31 has a shape of a curve of 90 degrees in the tubular body. In addition, a partitioning valve 32 for regulating the flow rate of the object to be measured may be disposed from the electromagnetic flowmeter at an interval of an introductory length of less than 5D. In this case, the object to be measured flowing in the flow path 7a in the measuring tube 4 of the electromagnetic flowmeter 1 becomes a non-axisymmetric flow (hereinafter referred to as a drift), and the detection accuracy of the induced electromotive force is lowered.

The electromagnetic flowmeter 1 according to the present embodiment adjusts the excitation current conducted to the coil unit 8 constituting a pair by the distribution of the magnetic field generated in the tube of the measuring tube 4 to adjust the distribution of the magnetic field It is an electronic flow meter (1).

Since the coil unit 8 is welded and covered with the peripheral wall portion 15 and the peripheral wall portion 16 after the electromagnetic flowmeter 1 is assembled, adjustment of the number of cores inserted into the coil 8a after assembly (See FIG. 1). The distribution of the magnetic field generated inside the measuring tube 4 is adjusted by adjusting the exciting current flowing through the coil unit 8 by the transducer 3 of the electromagnetic flowmeter 1. [

Fig. 15 is a diagram illustrating an adjusting mechanism 34 for adjusting the exciting current flowing through the coil unit 8. Fig. The converter (3) is provided with an adjusting mechanism (34) for adjusting the excitation current. The drive unit 33 (33A, 33B, 33C and 33D in Fig. 15) is provided for each pair of coil units 8 when a plurality of pairs of coil units 8 are formed (8A, 8B, 8C and 8D in Fig. 15) Are connected. The drive unit 33 is a device for adjusting the exciting current flowing through the coil unit 8 when the voltage Vcc is applied to the coil unit 8. The adjustment mechanism 34 can adjust the excitation current flowing through each coil unit 8 by controlling the drive unit 33 connected to each coil unit 8. [ Thereby, the adjusting mechanism (34) can adjust the electric field generated in the measuring tube (4).

As described above, the present embodiment adjusts the excitation current flowing through the coil unit 8 from the magnetic field distribution generated in the tube of the measurement tube 4 to detect the induced electromotive force with high accuracy against the drift of the measured object It is possible to achieve the effect.

Even when the magnetic field distribution in the measuring pipe 4 is adjusted by adjusting the exciting current as described above at the time of installing the electromagnetic flowmeter 1, There may be a difference between the measured value and the actual flow rate due to a flow with a strong disturbance of the measured object (hereinafter referred to as " turbulent flow ").

The flow rate of the object to be measured actually flowed to the electromagnetic flowmeter 1 and the measured value calculated by the electromagnetic flowmeter 1 are different from each other by the adjustment mechanism 34, It is possible to carry out the full-scale calibration in which the difference between the measured value and the actual flow rate is eliminated by adjusting the exciting current flowing through the flow path 8.

It is necessary to adjust the distribution of the magnetic field generated in the measuring tube 4 in order to correct the error between the measured amount of the electromagnetic flowmeter 1 and the actually measured object to be measured. Since the coil unit 8 is welded and covered with the peripheral wall portion 15 and the peripheral wall portion 16 after the electromagnetic flowmeter 1 is assembled, adjustment of the number of cores inserted into the coil 8a after assembly (See FIG. 1). The distribution of the magnetic field generated in the flow path 7a of the measuring tube 4 is adjusted by adjusting the exciting current conducted to the coil unit 8 by the converter 3 of the electromagnetic flowmeter 1. [ A drive unit 33 is connected to each coil unit 8 to be paired. By controlling each drive unit 33, the amount of current of exciting current flowing can be adjusted.

From the above, by adjusting the exciting current flowing through the coil unit 8 from the magnetic field distribution generated in the tube of the measuring tube 4 with respect to turbulence, the error between the measured amount of the electromagnetic flowmeter 1 and the actually measured object to be measured Can be generated. The present embodiment has the effect of eliminating the difference between the measured flow rate of the measured object flowing in the electromagnetic flowmeter 1 and the actual flow rate.

Embodiments 1 to 7 above exemplify a contact-type electromagnetic flowmeter in which an object to be measured and an electrode section are in contact with each other. The detection accuracy of the induced electromotive force of the electrode portion 9 is improved by covering the inner surface of the measuring tube other than the electrode portion 9 with the lining 6. [ However, the present invention is not limited to this type of contact-type electromagnetic flowmeter, and it may be a non-contact type electromagnetic flow meter in which other measurement types, for example, the object to be measured and the electrode portion 9 are not in contact with each other.

The electromagnetic flowmeter includes a detector 2 and a transducer 3 for amplifying a signal of the induced electromotive force detected by the detector 2 and converting the signal into a flow rate display, have. The present embodiment may be any of the fitting type and the separation type.

The adjustment mechanism 34 of the seventh embodiment can adjust the excitation current flowing through the coil unit 8 by the drive unit 33. The structure of the adjustment mechanism 34 is not limited to this. In the seventh embodiment, the adjustment mechanism 34 is incorporated in the converter 3. However, the adjustment mechanism 34 and the converter 3 may not be provided in the same housing but may be externally connected.

Although several embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These new embodiments can be implemented in various other forms, and various omissions, substitutions, and alterations can be made without departing from the gist of the invention. These embodiments and their modifications fall within the scope and spirit of the invention, and are included in the scope of equivalents to the invention described in the claims.

Claims (7)

A measuring tube through which the object to be measured flows,
A first coil disposed radially outward of the measuring tube and generating a magnetic field in the measuring tube;
A second coil disposed radially outward of the measuring tube so as to form a pair with the first coil and generating the magnetic field in the measuring tube;
A core member inserted in a radial direction of the measurement tube on an inner peripheral side of the first coil and the second coil,
And an electrode unit that is provided in the measurement tube and detects an induced electromotive force generated when the measured object flows into the measurement tube,
And,
The inner circumference of the first coil, the inner circumference of the second coil, and the outer diameter of the core member have a shape in which a plurality of the core members are insertable into the inner circumference of the first coil and the inner circumference of the second coil,
Wherein an inner circumference of the first coil and a number of the core members inserted into the inner circumference of the second coil are set according to a diameter of the measuring tube. And a third coil which is provided adjacent to the first coil and in the circumferential direction of the measuring tube and generates a magnetic field in the measuring tube,
A fourth coil that is adjacent to the second coil and in the circumferential direction of the measuring tube and is provided to form a pair with the third coil,
Further comprising:
The inner circumference of the third coil, the inner circumference of the fourth coil, and the outer diameter of the core member have a shape in which a plurality of the core members are insertable into the inner circumference of the third coil and the inner circumference of the fourth coil. The apparatus of claim 1, further comprising: a fifth coil provided adjacent to the first coil in the axial direction of the measuring tube, for generating a magnetic field in the measuring tube;
A sixth coil provided adjacent to the second coil in the axial direction of the measuring tube and paired with the fifth coil and generating a magnetic field in the measuring tube,
Further comprising:
The inner circumference of the fifth coil, the inner circumference of the sixth coil, and the outer diameter of the core member have a shape in which a plurality of the core members are insertable into the inner circumference of the fifth coil and the inner circumference of the sixth coil. The coil according to claim 2 or 3, wherein the number of the core members inserted into the inner periphery of the first coil
And the number of the core members inserted into the inner circumference of the second coil is different from the number of the core members inserted into the inner circumference of each of the other coils. 5. The method of claim 4, wherein the number of pairs of the pair of the first coil and the second coil and the pair of the pair of the fifth coil and the sixth coil, And the distance from the electrode portion is larger than the number of the core members of the pair adjacent to each other. The electromagnetic flowmeter according to claim 2, further comprising an adjustment mechanism for adjusting a current value of an excitation current flowing through each coil in accordance with a distribution of a magnetic field formed inside the measurement tube. The apparatus according to claim 6, wherein the adjusting mechanism is configured to adjust the currents of the exciting currents flowing through the respective coils depending on the difference between the measured value calculated from the induced electromotive force detected by the electrode portion and the actual flow rate of the measured object passed through the measuring tube An electronic flow meter that adjusts the value.

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